RNA-activated protein kinase (PKR) is a key component of the interferon-induced antiviral pathway in higher eukaryotes. Upon recognition of viral dsRNA, PKR is activated via dimerization and autophosphorylation. PKR contains two N-terminal dsRNA binding domains (dsRBD) and a C-terminal kinase domain. The dsRBDs and the kinase are separated by a long, unstructured ∼80-amino acid linker in the human enzyme. The length of the N-terminal portion of the linker varies among PKR sequences, and it is completely absent in one ortholog. Here, we characterize the effects of deleting the variable region from the human enzyme to produce PKRΔV. The linker deletion results in quantitative but not qualitative changes in catalytic activity, RNA binding, and conformation. PKRΔV is somewhat more active and exhibits more cooperative RNA binding. As we previously observed for the full-length enzyme, PKRΔV is flexible in solution and adopts a range of compact and extended conformations. The conformational ensemble is biased toward compact states that might be related to weak interactions between the dsRBD and kinase domains. PKR retains RNA-induced autophosphorylation upon complete removal of the linker, indicating that the C-terminal, basic region is also not required for activity.

PKR is a member of the eIF2α family of protein kinases that inhibit translational initiation in response to stress stimuli and functions as a key mediator of the interferon-induced antiviral response. PKR contains a dsRNA binding domain that binds to duplex regions present in viral RNAs, resulting in kinase activation and autophosphorylation. An emerging theme in the regulation of protein kinases is the allosteric linkage of dimerization and activation. The PKR kinase domain forms a back-to-back parallel dimer that is implicated in activation. We have developed a sensitive homo-Förster resonance energy transfer assay for kinase domain dimerization to directly probe the relationship among RNA binding, activation, and dimerization. In the case of perfect duplex RNAs, dimerization is correlated with activation and dsRNAs containing 30 bp or more efficiently induce kinase domain dimerization and activation. However, more complex duplex RNAs containing a 10–15 bp 2′-O-methyl RNA barrier produce kinase dimers but do not activate. Similarly, inactivating mutations within the PKR dimer interface that disrupt key electrostatic and hydrogen binding interactions fail to abolish dimerization. Our data support a model in which activating RNAs induce formation of a back-to-back parallel PKR kinase dimer whereas nonactivating RNAs either fail to induce dimerization or produce an alternative, inactive dimer configuration, providing an additional mechanism for distinguishing between host and pathogen RNA.

The Sec pathway mediates translocation of protein across the inner membrane of bacteria. SecA is a motor protein that drives translocation of preprotein through the SecYEG channel. SecA reversibly dimerizes under physiological conditions, but different dimer interfaces have been observed in SecA crystal structures. Here, we have used biophysical approaches to address the nature of the SecA dimer that exists in solution. We have taken advantage of the extreme salt sensitivity of SecA dimerization to compare the rates of hydrogen–deuterium exchange of the monomer and dimer and have analyzed the effects of single-alanine substitutions on dimerization affinity. Our results support the antiparallel dimer arrangement observed in one of the crystal structures of Bacillus subtilis SecA. Additional residues lying within the preprotein binding domain and the C-terminus are also protected from exchange upon dimerization, indicating linkage to a conformational transition of the preprotein binding domain from an open to a closed state. In agreement with this interpretation, normal mode analysis demonstrates that the SecA dimer interface influences the global dynamics of SecA such that dimerization stabilizes the closed conformation.

Sedimentation velocity analytical ultracentrifugation is a classical biophysical technique that is commonly used to analyze the size, shape, and interactions of biological macromolecules in solution. Fluorescence detection provides enhanced sensitivity and selectivity relative to the standard absorption and refractrometric detectors, but data acquisition is more complex and can be subject to interference from several photophysical effects. Here, we describe methods to configure sedimentation velocity measurements using fluorescence detection and evaluate the performance of the fluorescence optical system. The fluorescence detector output is linear over a concentration range of at least 1 to 500 nM fluorescein and Alexa Fluor 488. At high concentrations, deviations from linearity can be attributed to the inner filter effect. A duplex DNA labeled with Alexa Fluor 488 was used as a standard to compare sedimentation coefficients obtained using fluorescence and absorbance detectors. Within error, the sedimentation coefficients agree. Thus, the fluorescence detector is capable of providing precise and accurate sedimentation velocity results that are consistent with measurements performed using conventional absorption optics, provided the data are collected at appropriate sample concentrations and the optics are configured correctly.

Protein kinase R (PKR) is an interferon-induced kinase that plays a pivotal role in the innate immunity response to viral infection. PKR is activated upon binding to double-stranded RNA (dsRNA). Our previous analysis of binding of PKR to dsRNAs ranging from 20 to 40 bp supports a dimerization model for activation in which 30 bp represents the minimal length required to bind two PKR monomers and activate PKR via autophosphorylation. These studies were complicated by the formation of protein–RNA aggregates, particularly at low salt concentrations using longer dsRNAs. Here, we have taken advantage of the enhanced sensitivity afforded using fluorescence-detected analytical ultracentrifugation to reduce the RNA concentrations from micromolar to nanomolar. Under these conditions, we are able to characterize high-affinity binding of PKR to longer dsRNAs in 75 mM NaCl. The PKR binding stoichiometries are increased at lower salt concentrations but remain lower than those previously obtained for the dsRNA binding domain. The dependence of the limiting PKR binding stoichiometries on dsRNA length does not conform to standard models for nonspecific binding and suggests that binding to longer sequences occurs via a different binding mode with a larger site size. Although dimerization plays a key role in the PKR activation mechanism, the ability of shorter dsRNAs to bind two PKR monomers is not sufficient to induce autophosphorylation. We propose that activation of PKR by longer RNAs is correlated with an alternative binding mode in which both of the dsRNA binding motifs contact the RNA, inducing PKR to dimerize via a direct interaction of the kinase domains.

PKR (protein kinase R) is induced by interferon and is a key component of the innate immunity antiviral pathway. Upon binding double-stranded RNA (dsRNA) or dimerization in the absence of dsRNA, PKR undergoes autophosphorylation at multiple serines and threonines that activate the kinase. Although it has previously been demonstrated that phosphorylation enhances PKR dimerization, gel filtration analysis reveals a second monomeric phosphorylated form. These forms are termed phosphorylated dimeric PKR (pPKRd) and phosphorylated monomeric PKR (pPKRm). These two forms do not reversibly interconvert. Sedimentation equilibrium measurements reveal that pPKRm dimerizes weakly with a Kd similar to that of unphosphorylated PKR. Isoelectric focusing and mass spectrometry demonstrate that both pPKRm and pPKRd are heterogeneous in their phosphorylation states, with an average of 9 or 10 phosphates. Equilibrium chemical denaturation analysis indicates that phosphorylation destabilizes the kinase domain by ∼1.5 kcal/mol in the dimeric form but not in the monomeric form. Limited proteolysis also reveals that phosphorylation induces a conformational change in pPKRd that is not detected in pPKRm. pPKRm binds dsRNA with an affinity similar to that of unphosphorylated PKR, whereas binding cannot be detected with pPKRd. Despite these substantial differences in biophysical properties, both pPKRm and pPKRd are catalytically competent and are activated to phosphorylate the PKR substrate eIF2α in the absence of dsRNA. Thus, both monomeric and dimeric forms of phosphorylated PKR may participate in the interferon antiviral pathway.

PKR (protein kinase R) is induced by interferon and is a key component of the innate immunity antiviral pathway. Upon binding dsRNA, PKR undergoes autophosphorylation reactions that activate the kinase, leading it to phosphorylate eIF2α, thus inhibiting protein synthesis in virally infected cells. PKR contains a dsRNA-binding domain (dsRBD) and a kinase domain. The dsRBD is composed of two tandem dsRNA-binding motifs. An autoinhibition model for PKR has been proposed, whereby dsRNA binding activates the enzyme by inducing a conformational change that relieves the latent enzyme of the inhibition that is mediated by the interaction of the dsRBD with the kinase. However, recent biophysical data support an open conformation for the latent enzyme, where activation is mediated by dimerization of PKR induced upon binding dsRNA. We have probed the importance of interdomain contacts by comparing the relative stabilities of isolated domains with the same domain in the context of the intact enzyme using equilibrium chemical denaturation experiments. The two dsRNA-binding motifs fold independently, with the C-terminal motif exhibiting greater stability. The kinase domain is stabilized by about 1.5 kcal/mol in the context of the holenzyme, and we detect low-affinity binding of the kinase and dsRBD constructs in solution, indicating that these domains interact weakly. Limited proteolysis measurements confirm the expected domain boundaries and reveal that the activation loop in the kinase is accessible to cleavage and unstructured. Autophosphorylation induces a conformation change that blocks proteolysis of the activation loop.

Protein–nucleic acid interactions govern a variety of processes, including replication, transcription, recombination and repair. These interactions take place in both sequence-specific and non-specific modes, and the latter occur in many biologically significant contexts. Analytical ultracentrifugation is a useful method for the detailed characterization of the stoichiometry and affinity of macromolecular interactions in free solution. There has been a resurgence of interest in the application of sedimentation equilibrium methods to protein–nucleic acid interactions. However, these studies have been generally focused on sequence–specific interactions. Here we describe an approach to analyze non-specific interactions using sedimentation equilibrium. We have adapted an existing model for non-specific interaction of proteins with finite, one-dimensional nucleic acid lattices for global fitting of multiwavelength sedimentation equilibrium data. The model is extended to accommodate protein binding to multiple faces of the nucleic acid, resulting in overlap of consecutive ligands along the sequence of the RNA or DNA. The approach is illustrated in a sedimentation equilibrium analysis of the interaction of the double-stranded RNA binding motif of protein kinase R with a 20-basepair RNA construct.

Protein kinase R (PKR) is activated by dsRNA produced during virus replication and plays a major role in the innate immunity response to virus infection. In response, viruses have evolved multiple strategies to evade PKR. Adenovirus virus-associated RNA-I (VAI) is a short, noncoding transcript that functions as an RNA decoy to sequester PKR in an inactive state. VAI consists of an apical stem-loop, a highly structured central domain, and a terminal stem. Chemical probing and mutagenesis demonstrate that the central domain is stabilized by a pseudoknot. A structural model of VAI was obtained from constraints derived from chemical probing and small angle x-ray scattering (SAXS) measurements. VAI adopts a flat, extended conformation with the apical and terminal stems emanating from a protuberance in the center. This model reveals how the apical stem and central domain assemble to produce an extended duplex that is precisely tuned to bind a single PKR monomer with high affinity, thereby inhibiting activation of PKR by viral dsRNA.

Protein kinase R (PKR) is a central component of the interferon antiviral defense pathway. Upon binding double-stranded RNA (dsRNA), PKR undergoes autophosphorylation reactions that activate the kinase. PKR then phosphorylates eukaryotic initiation factor 2α, thus inhibiting protein synthesis in virally infected cells. Using a series of dsRNAs of increasing length, we define the mechanism of PKR activation. A minimal dsRNA of 30 bp is required to bind two PKR monomers and 30 bp is the smallest dsRNA that elicits autophosphorylation activity. Thus, the ability of dsRNAs to function as PKR activators is correlated with binding of two or more PKR monomers. Sedimentation velocity data fit a model where PKR monomers sequentially attach to a single dsRNA. These results support an activation mechanism where the role of the dsRNA is to bring two or more PKR monomers in close proximity to enhance dimerization via the kinase domain. This model explains the inhibition observed at high dsRNA concentrations and the strong dependence of maximum activation on dsRNA binding affinity. Binding affinities increase dramatically upon reducing the salt concentration from 200 to 75 mM NaCl and we observe that a second PKR can bind to the 20-bp dsRNA. Nonspecific assembly of PKR on dsRNA occurs stochastically without apparent cooperativity.

Transport of many proteins to extracytoplasmic locations occurs via the general secretion (Sec) pathway. In Escherichia coli, this pathway is composed of the SecYEG protein-conducting channel and the SecA ATPase. SecA plays a central role in binding the signal peptide region of preproteins, directing preproteins to membrane-bound SecYEG and promoting translocation coupled with ATP hydrolysis. Although it is well established that SecA is crucial for preprotein transport and thus cell viability, its oligomeric state during different stages of transport remains ill defined. We have characterized the energetics of SecA dimerization as a function of salt concentration and temperature and defined the linkage of SecA dimerization and signal peptide binding using analytical ultracentrifugation. The use of a new fluorescence detector permitted an analysis of SecA dimerization down to concentrations as low as 50 nM. The dimer dissociation constants are strongly dependent on salt. Linkage analysis indicates that SecA dimerization is coupled to the release of about five ions, demonstrating that electrostatic interactions play an important role in stabilizing the SecA dimer interface. Binding of signal peptide reduces SecA dimerization affinity, such that Kd increases about 9-fold from 0.28 μM in the absence of peptide to 2.68 μM in the presence of peptide. The weakening of the SecA dimer that accompanies signal peptide binding may poise the SecA dimer to dissociate upon binding to SecYEG.Download high-res image (189KB)Download full-size image

•Divalent ion regulates PKR binding to VAI RNA.•PKR binds weakly to the isolated VAI domains.•The apical stem and the central domain together form a high-affinity PKR binding site.Protein kinase R (PKR) is a component of the innate immunity antiviral pathway. PKR is activated upon binding to double-stranded RNA (dsRNA) to undergo dimerization and autophosphorylation. Adenovirus-associated RNA I (VAI) is a short, non-coding transcript whose major function is to inhibit the activity of PKR. VAI contains three domains: an apical stem–loop, a highly structured central domain, and a terminal stem. Previous studies have localized PKR binding to the apical stem and to the central domain. However, the molecular mechanism for inhibition of PKR is not known. We have characterized the stoichiometry and affinity of PKR binding to VAI and several domain constructs using analytical ultracentrifugation and correlated VAI binding and PKR inhibition. Although PKR binding to simple dsRNAs is not regulated by divalent ion, analysis of the interaction of the isolated dsRNA binding domain with VAI reveals that the binding affinity is enhanced by divalent ion. Dissection of VAI into its constituent domains indicates that none of the isolated domains retains the PKR binding affinity or inhibitory potency of the full-length RNA. PKR is capable of binding the isolated terminal stem, but deletion of this domain from VAI does not affect PKR binding or inhibition. These results indicate that both the apical stem and the central domain are required to form a high-affinity PKR binding site. Our data support a model whereby VAI functions as a PKR inhibitor because it binds a monomer tightly but does not facilitate dimerization.Download high-res image (49KB)Download full-size image

Protein kinase R (PKR) is an interferon-induced kinase that plays a pivotal role in the innate immunity pathway. PKR is activated to undergo autophosphorylation upon binding to double-stranded RNAs or RNAs that contain duplex regions. Activated PKR phosphorylates the α subunit of eukaryotic initiation factor 2, thereby inhibiting protein synthesis. PKR is also activated by heparin, a highly sulfated glycosaminoglycan. We have used biophysical methods to define the mechanism of PKR activation by heparin. Heparins as short as hexasaccharide bind strongly to PKR and activate autophosphorylation. In contrast to double-stranded RNA, heparin activates PKR by binding to the kinase domain. Analytical ultracentrifugation measurements support a thermodynamic linkage model where heparin binding allosterically enhances PKR dimerization, thereby activating the kinase. These results indicate that PKR can be activated by small molecules and represents a viable target for the development of novel antiviral agents.Download high-res image (218KB)Download full-size imageHighlights► Short heparin oligosaccharides activate PKR. ► Heparin binding enhances PKR dimerization via thermodynamic linkage. ► PKR activation by heparin is mediated by enhanced dimerization. ► Heparin binds to a positively charged cleft on the PKR kinase domain.

The double-stranded RNA (dsRNA)-activated protein kinase [protein kinase R (PKR)] plays a major role in the innate immune response in humans. PKR binds dsRNA non-sequence specifically and requires a minimum of 15-bp dsRNA for one protein to bind and 30-bp dsRNA to induce protein dimerization and activation by autophosphorylation. PKR phosphorylates eukaryotic initiation factor 2α, a translation initiation factor, resulting in the inhibition of protein synthesis. We investigated the mechanism of PKR activation by an RNA hairpin with a number of base pairs intermediate between these 15- to 30-bp limits: human immunodeficiency virus type 1 transactivation-responsive region (TAR) RNA, a 23-bp hairpin with three bulges that is known to dimerize. TAR monomers and dimers were isolated from native gels and assayed for RNA and protein dimerization to test whether RNA dimerization affects PKR dimerization and activation. To modulate the extent of dimerization, we included TAR mutants with different secondary features. Native gel mixing experiments and analytical ultracentrifugation indicate that TAR monomers bind one PKR monomer and that TAR dimers bind two or three PKRs, demonstrating that RNA dimerization drives the binding of multiple PKR molecules. Consistent with functional dimerization of PKR, TAR dimers activated PKR while TAR monomers did not, and RNA dimers with fewer asymmetrical secondary-structure defects, as determined by enzymatic structure mapping, were more potent activators. Thus, the secondary-structure defects in the TAR RNA stem function as antideterminants to PKR binding and activation. Our studies support that dimerization of a 15- to 30-bp hairpin RNA, which effectively doubles its length, is a key step in driving activation of PKR and provide a model for how RNA folding can be related to human disease.

Protein kinase R (PKR) is a key component of the interferon antiviral defense pathway. Upon binding double-stranded RNA, PKR undergoes autophosphorylation reactions that activate the kinase. PKR contains an N-terminal double-stranded RNA binding domain, which consists of two tandem double-stranded RNA binding motifs, and a C-terminal kinase domain. We have used small-angle X-ray scattering and small-angle neutron scattering to define the conformation of latent PKR in solution. Guinier analysis indicates a radius of gyration of about 35 Å. The p(r) distance distribution function exhibits a peak near 30 Å, with a broad shoulder extending to longer distances. Good fits to the scattering data require models that incorporate multiple compact and extended conformations of the two interdomain linker regions. Thus, PKR belongs to the growing family of proteins that contain intrinsically unstructured regions. We propose that the flexible linkers may allow PKR to productively dimerize upon interaction with RNA activators that have diverse structures.

Protein kinase R (PKR) is an interferon-induced kinase that plays a pivotal role in the innate immunity pathway for defense against viral infection. PKR is activated to undergo autophosphorylation upon binding to RNAs that contain duplex regions. Activated PKR phosphorylates the α-subunit of eukaryotic initiation factor 2, thereby inhibiting protein synthesis in virus-infected cells. Viruses have evolved diverse PKR-inhibitory strategies to evade the antiviral response. Adenovirus encodes virus-associated RNA I (VAI), a highly structured RNA inhibitor that binds PKR but fails to activate. We have characterized the stoichiometry and affinity of PKR binding to define the mechanism of PKR inhibition by VAI. Sedimentation velocity and isothermal titration calorimetry measurements indicate that PKR interactions with VAI are modulated by Mg2+. Two PKR monomers bind in the absence of Mg2+, but a single monomer binds in the presence of divalent ion. Known RNA activators of PKR are capable of binding multiple PKR monomers to allow the kinase domains to come into close proximity and thus enhance dimerization. We propose that VAI acts as an inhibitor of PKR because it binds and sequesters a single PKR in the presence of divalent cation.Graphical AbstractDownload high-res image (83KB)Download full-size imageResearch Highlights► The VAI RNA of Adenovirus functions to inhibit PKR. ► PKR interactions with VAI are modulated by Mg2+. ► A single PKR monomer binds to VAI in the presence of divalent ion. ► VAI inhibits PKR because it does not foster PKR dimerization in the presence of Mg2+.